Protocol Buffers - Google's data interchange format (grpc依赖) https://developers.google.com/protocol-buffers/
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/*
* Copyright (c) 2009-2021, Google LLC
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of Google LLC nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL Google LLC BE LIABLE FOR ANY DIRECT,
* INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "upb/mem/arena_internal.h"
#include "upb/port/atomic.h"
// Must be last.
#include "upb/port/def.inc"
struct _upb_MemBlock {
// Atomic only for the benefit of SpaceAllocated().
UPB_ATOMIC(_upb_MemBlock*) next;
uint32_t size;
// Data follows.
};
static const size_t memblock_reserve =
UPB_ALIGN_UP(sizeof(_upb_MemBlock), UPB_MALLOC_ALIGN);
typedef struct _upb_ArenaRoot {
upb_Arena* root;
uintptr_t tagged_count;
} _upb_ArenaRoot;
static _upb_ArenaRoot _upb_Arena_FindRoot(upb_Arena* a) {
uintptr_t poc = upb_Atomic_Load(&a->parent_or_count, memory_order_acquire);
while (_upb_Arena_IsTaggedPointer(poc)) {
upb_Arena* next = _upb_Arena_PointerFromTagged(poc);
UPB_ASSERT(a != next);
uintptr_t next_poc =
upb_Atomic_Load(&next->parent_or_count, memory_order_acquire);
if (_upb_Arena_IsTaggedPointer(next_poc)) {
// To keep complexity down, we lazily collapse levels of the tree. This
// keeps it flat in the final case, but doesn't cost much incrementally.
//
// Path splitting keeps time complexity down, see:
// https://en.wikipedia.org/wiki/Disjoint-set_data_structure
//
// We can safely use a relaxed atomic here because all threads doing this
// will converge on the same value and we don't need memory orderings to
// be visible.
//
// This is true because:
// - If no fuses occur, this will eventually become the root.
// - If fuses are actively occuring, the root may change, but the
// invariant is that `parent_or_count` merely points to *a* parent.
//
// In other words, it is moving towards "the" root, and that root may move
// further away over time, but the path towards that root will continue to
// be valid and the creation of the path carries all the memory orderings
// required.
UPB_ASSERT(a != _upb_Arena_PointerFromTagged(next_poc));
upb_Atomic_Store(&a->parent_or_count, next_poc, memory_order_relaxed);
}
a = next;
poc = next_poc;
}
return (_upb_ArenaRoot){.root = a, .tagged_count = poc};
}
size_t upb_Arena_SpaceAllocated(upb_Arena* arena) {
arena = _upb_Arena_FindRoot(arena).root;
size_t memsize = 0;
while (arena != NULL) {
_upb_MemBlock* block =
upb_Atomic_Load(&arena->blocks, memory_order_relaxed);
while (block != NULL) {
memsize += sizeof(_upb_MemBlock) + block->size;
block = upb_Atomic_Load(&block->next, memory_order_relaxed);
}
arena = upb_Atomic_Load(&arena->next, memory_order_relaxed);
}
return memsize;
}
uint32_t upb_Arena_DebugRefCount(upb_Arena* a) {
// These loads could probably be relaxed, but given that this is debug-only,
// it's not worth introducing a new variant for it.
uintptr_t poc = upb_Atomic_Load(&a->parent_or_count, memory_order_acquire);
while (_upb_Arena_IsTaggedPointer(poc)) {
a = _upb_Arena_PointerFromTagged(poc);
poc = upb_Atomic_Load(&a->parent_or_count, memory_order_acquire);
}
return _upb_Arena_RefCountFromTagged(poc);
}
static void upb_Arena_AddBlock(upb_Arena* a, void* ptr, size_t size) {
_upb_MemBlock* block = ptr;
// Insert into linked list.
block->size = (uint32_t)size;
upb_Atomic_Init(&block->next, a->blocks);
upb_Atomic_Store(&a->blocks, block, memory_order_release);
a->head.ptr = UPB_PTR_AT(block, memblock_reserve, char);
a->head.end = UPB_PTR_AT(block, size, char);
UPB_POISON_MEMORY_REGION(a->head.ptr, a->head.end - a->head.ptr);
}
static bool upb_Arena_AllocBlock(upb_Arena* a, size_t size) {
if (!a->block_alloc) return false;
_upb_MemBlock* last_block = upb_Atomic_Load(&a->blocks, memory_order_acquire);
size_t last_size = last_block != NULL ? last_block->size : 128;
size_t block_size = UPB_MAX(size, last_size * 2) + memblock_reserve;
_upb_MemBlock* block = upb_malloc(upb_Arena_BlockAlloc(a), block_size);
if (!block) return false;
upb_Arena_AddBlock(a, block, block_size);
return true;
}
void* _upb_Arena_SlowMalloc(upb_Arena* a, size_t size) {
if (!upb_Arena_AllocBlock(a, size)) return NULL; /* Out of memory. */
UPB_ASSERT(_upb_ArenaHas(a) >= size);
return upb_Arena_Malloc(a, size);
}
/* Public Arena API ***********************************************************/
static upb_Arena* upb_Arena_InitSlow(upb_alloc* alloc) {
const size_t first_block_overhead = sizeof(upb_Arena) + memblock_reserve;
upb_Arena* a;
/* We need to malloc the initial block. */
char* mem;
size_t n = first_block_overhead + 256;
if (!alloc || !(mem = upb_malloc(alloc, n))) {
return NULL;
}
a = UPB_PTR_AT(mem, n - sizeof(*a), upb_Arena);
n -= sizeof(*a);
a->block_alloc = upb_Arena_MakeBlockAlloc(alloc, 0);
upb_Atomic_Init(&a->parent_or_count, _upb_Arena_TaggedFromRefcount(1));
upb_Atomic_Init(&a->next, NULL);
upb_Atomic_Init(&a->tail, a);
upb_Atomic_Init(&a->blocks, NULL);
upb_Arena_AddBlock(a, mem, n);
return a;
}
upb_Arena* upb_Arena_Init(void* mem, size_t n, upb_alloc* alloc) {
upb_Arena* a;
if (n) {
/* Align initial pointer up so that we return properly-aligned pointers. */
void* aligned = (void*)UPB_ALIGN_UP((uintptr_t)mem, UPB_MALLOC_ALIGN);
size_t delta = (uintptr_t)aligned - (uintptr_t)mem;
n = delta <= n ? n - delta : 0;
mem = aligned;
}
/* Round block size down to alignof(*a) since we will allocate the arena
* itself at the end. */
n = UPB_ALIGN_DOWN(n, UPB_ALIGN_OF(upb_Arena));
if (UPB_UNLIKELY(n < sizeof(upb_Arena))) {
return upb_Arena_InitSlow(alloc);
}
a = UPB_PTR_AT(mem, n - sizeof(*a), upb_Arena);
upb_Atomic_Init(&a->parent_or_count, _upb_Arena_TaggedFromRefcount(1));
upb_Atomic_Init(&a->next, NULL);
upb_Atomic_Init(&a->tail, a);
upb_Atomic_Init(&a->blocks, NULL);
a->block_alloc = upb_Arena_MakeBlockAlloc(alloc, 1);
a->head.ptr = mem;
a->head.end = UPB_PTR_AT(mem, n - sizeof(*a), char);
return a;
}
static void arena_dofree(upb_Arena* a) {
UPB_ASSERT(_upb_Arena_RefCountFromTagged(a->parent_or_count) == 1);
while (a != NULL) {
// Load first since arena itself is likely from one of its blocks.
upb_Arena* next_arena =
(upb_Arena*)upb_Atomic_Load(&a->next, memory_order_acquire);
upb_alloc* block_alloc = upb_Arena_BlockAlloc(a);
_upb_MemBlock* block = upb_Atomic_Load(&a->blocks, memory_order_acquire);
while (block != NULL) {
// Load first since we are deleting block.
_upb_MemBlock* next_block =
upb_Atomic_Load(&block->next, memory_order_acquire);
upb_free(block_alloc, block);
block = next_block;
}
a = next_arena;
}
}
void upb_Arena_Free(upb_Arena* a) {
uintptr_t poc = upb_Atomic_Load(&a->parent_or_count, memory_order_acquire);
retry:
while (_upb_Arena_IsTaggedPointer(poc)) {
a = _upb_Arena_PointerFromTagged(poc);
poc = upb_Atomic_Load(&a->parent_or_count, memory_order_acquire);
}
// compare_exchange or fetch_sub are RMW operations, which are more
// expensive then direct loads. As an optimization, we only do RMW ops
// when we need to update things for other threads to see.
if (poc == _upb_Arena_TaggedFromRefcount(1)) {
arena_dofree(a);
return;
}
if (upb_Atomic_CompareExchangeWeak(
&a->parent_or_count, &poc,
_upb_Arena_TaggedFromRefcount(_upb_Arena_RefCountFromTagged(poc) - 1),
memory_order_release, memory_order_acquire)) {
// We were >1 and we decremented it successfully, so we are done.
return;
}
// We failed our update, so someone has done something, retry the whole
// process, but the failed exchange reloaded `poc` for us.
goto retry;
}
static void _upb_Arena_DoFuseArenaLists(upb_Arena* const parent,
upb_Arena* child) {
upb_Arena* parent_tail = upb_Atomic_Load(&parent->tail, memory_order_relaxed);
do {
// Our tail might be stale, but it will always converge to the true tail.
upb_Arena* parent_tail_next =
upb_Atomic_Load(&parent_tail->next, memory_order_relaxed);
while (parent_tail_next != NULL) {
parent_tail = parent_tail_next;
parent_tail_next =
upb_Atomic_Load(&parent_tail->next, memory_order_relaxed);
}
upb_Arena* displaced =
upb_Atomic_Exchange(&parent_tail->next, child, memory_order_relaxed);
parent_tail = upb_Atomic_Load(&child->tail, memory_order_relaxed);
// If we displaced something that got installed racily, we can simply
// reinstall it on our new tail.
child = displaced;
} while (child != NULL);
upb_Atomic_Store(&parent->tail, parent_tail, memory_order_relaxed);
}
static upb_Arena* _upb_Arena_DoFuse(upb_Arena* a1, upb_Arena* a2,
uintptr_t* ref_delta) {
// `parent_or_count` has two disctint modes
// - parent pointer mode
// - refcount mode
//
// In parent pointer mode, it may change what pointer it refers to in the
// tree, but it will always approach a root. Any operation that walks the
// tree to the root may collapse levels of the tree concurrently.
_upb_ArenaRoot r1 = _upb_Arena_FindRoot(a1);
_upb_ArenaRoot r2 = _upb_Arena_FindRoot(a2);
if (r1.root == r2.root) return r1.root; // Already fused.
// Avoid cycles by always fusing into the root with the lower address.
if ((uintptr_t)r1.root > (uintptr_t)r2.root) {
_upb_ArenaRoot tmp = r1;
r1 = r2;
r2 = tmp;
}
// The moment we install `r1` as the parent for `r2` all racing frees may
// immediately begin decrementing `r1`'s refcount (including pending
// increments to that refcount and their frees!). We need to add `r2`'s refs
// now, so that `r1` can withstand any unrefs that come from r2.
//
// Note that while it is possible for `r2`'s refcount to increase
// asynchronously, we will not actually do the reparenting operation below
// unless `r2`'s refcount is unchanged from when we read it.
//
// Note that we may have done this previously, either to this node or a
// different node, during a previous and failed DoFuse() attempt. But we will
// not lose track of these refs because we always add them to our overall
// delta.
uintptr_t r2_untagged_count = r2.tagged_count & ~1;
uintptr_t with_r2_refs = r1.tagged_count + r2_untagged_count;
if (!upb_Atomic_CompareExchangeStrong(
&r1.root->parent_or_count, &r1.tagged_count, with_r2_refs,
memory_order_release, memory_order_acquire)) {
return NULL;
}
// Perform the actual fuse by removing the refs from `r2` and swapping in the
// parent pointer.
if (!upb_Atomic_CompareExchangeStrong(
&r2.root->parent_or_count, &r2.tagged_count,
_upb_Arena_TaggedFromPointer(r1.root), memory_order_release,
memory_order_acquire)) {
// We'll need to remove the excess refs we added to r1 previously.
*ref_delta += r2_untagged_count;
return NULL;
}
// Now that the fuse has been performed (and can no longer fail) we need to
// append `r2` to `r1`'s linked list.
_upb_Arena_DoFuseArenaLists(r1.root, r2.root);
return r1.root;
}
static bool _upb_Arena_FixupRefs(upb_Arena* new_root, uintptr_t ref_delta) {
if (ref_delta == 0) return true; // No fixup required.
uintptr_t poc =
upb_Atomic_Load(&new_root->parent_or_count, memory_order_relaxed);
if (_upb_Arena_IsTaggedPointer(poc)) return false;
uintptr_t with_refs = poc - ref_delta;
UPB_ASSERT(!_upb_Arena_IsTaggedPointer(with_refs));
return upb_Atomic_CompareExchangeStrong(&new_root->parent_or_count, &poc,
with_refs, memory_order_relaxed,
memory_order_relaxed);
}
bool upb_Arena_Fuse(upb_Arena* a1, upb_Arena* a2) {
if (a1 == a2) return true; // trivial fuse
// Do not fuse initial blocks since we cannot lifetime extend them.
// Any other fuse scenario is allowed.
if (upb_Arena_HasInitialBlock(a1) || upb_Arena_HasInitialBlock(a2)) {
return false;
}
// The number of refs we ultimately need to transfer to the new root.
uintptr_t ref_delta = 0;
while (true) {
upb_Arena* new_root = _upb_Arena_DoFuse(a1, a2, &ref_delta);
if (new_root != NULL && _upb_Arena_FixupRefs(new_root, ref_delta)) {
return true;
}
}
}